90 / 2018-06-29 14:05:23
3D Printing of Multi-scale Scaffolds by On/off Electrohydrodynamic Field
3D scaffold,3D printing,Melt electrospinning writing,Multi-scale scaffold,Cell culture
Abstract Accepted
Wang Peng / Zhejiang University
Gao Qing / Zhejiang University
Xie Chaoqi / Zhejiang University
Zeng Jiahui / Zhejiang University
Fu Jainzhong / Zhejiang University
He Yong / Zhejiang University
In tissue engineering, three-dimensional(3D) porous structures is critical to facilitate cell attachment, growth and proliferation. Traditional fused deposition modeling (FDM) has a limitation whereby its patterning resolution is too low at around 200μm, therefore, it can’t implement advanced biomedical functions. Recently, melt electrospinning writing (MEW) has received much attention for well controlled micro-scale structures manufacturing at round 10μm, however, it can’t offer enough strength support. In this paper, we combine the two techniques to fabricate multi-scale PCL-based scaffolds, where FDM offer the macro shape and strength support, and MEW offer a favorable environment for cell growth. First, micro-scale pattern was fabricated by MEW, Next, macro-scale pattern was fabricated by FDM. Then, repeat the previous two step. Finally, we can obtain the well controlled 3D cross-scale scaffolds at both macro scale and micro scale. Cell viability, proliferation, and morphology were systematically studied, and the result indicate that the multi-scale scaffolds were favorable for cell attachment and growth.
Important Date
  • Conference Date

    Aug 26

    2018

    to

    Aug 28

    2018

  • Apr 09 2018

    Abstract Submission Deadline

  • May 01 2018

    Draft paper submission deadline

  • Aug 01 2018

    Abstract Notification of Acceptance

  • Aug 01 2018

    Draft Paper Acceptance Notification

  • Aug 28 2018

    Registration deadline

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